Trials / Completed

CompletedNCT06247943

Lung Protective Ventilation Strategies

Lung Protective Ventilation Strategies to Improve Oxygenation Function and Respiratory Mechanics in Patients Undergoing Robotic Bariatric Surgery

Summary

Obesity is becoming a common condition and bariatric metabolic surgery is one of the main options for treating morbid obesity. However, since most patients undergoing robotic bariatric surgery are class III obese, it brings new challenges to perioperative anesthesia management. Here, we explored the effects of lung-protective ventilation strategies on pulmonary oxygenation function and respiratory mechanics in patients undergoing robotic bariatric surgery.

Detailed description

Forty obese patients who underwent robotic bariatric surgery in our hospital were selected and randomly divided into a lung-protective ventilation strategy group (Group P) and a control group (Group C). The volume-controlled mode was used to assist ventilation, and the inspiratory/expiratory ratio (I: E) was 1:2. Tidal volume (VT) was set according to the Predicted body weight (PBW) throughout the whole procedure, and in group C, VT was 9 ml /kg without Positive end-expiratory pressure (PEEP), and the inhaled oxygen concentration (Fraction of oxygen) was 0.5 ml /kg, while the inspiratory oxygen concentration (Fraction of oxygen) was 0.5 ml /kg. Group C: VT 9ml /kg, no Positive end-expiratory pressure (PEEP), Fraction of inspiration O2 (FiO2) of 60%; Group P: the ventilation mode was the same as that of Group C from tracheal intubation to the beginning of pneumoperitoneum for 10 minutes, and after 10 minutes of pneumoperitoneum, the ventilation mode was the same as that of Group C. After the pneumoperitoneum for 10 minutes, the ventilation mode was VT 7ml/kg, PEEP 6cmH2O, FiO2 of 40%, and the plateau pressure was maintained at \<30cmH2O. In both groups, the intraoperative gas flow was 2L/min, and SpO2 was maintained at ≥95%; if it could not be maintained, the oxygenation function of the patients could be improved by adjusting the ventilation parameters and strategies; meanwhile, the respiratory rate (RR) was adjusted to maintain the End-tidal carbon dioxide partial pressure (PETCO2) at ≥30%, and the end-tidal carbon dioxide partial pressure (PETCO2) was maintained at ≥30%, and the end-tidal carbon dioxide partial pressure (PETCO2) was maintained at ≥30%. The respiratory mechanical parameters: tidal volume, RR, airway peak pressure (PPeak), plateau pressure (PPeak), and plateau pressure (PPeak) were recorded at 5 minutes after tracheal intubation (T0), 10 minutes after the start of the pneumoperitoneum (T1), 60 minutes (T2), 120 minutes (T3), and 10 minutes after the pneumoperitoneum was closed (T4). pressure (PPeak), and plateau pressure (PPlate), and calculate the dynamic lung compliance; arterial blood was drawn at T0, T1, T2, T3, and T4, respectively, and the arterial partial pressure of oxygen (PaO2) and the arterial partial pressure of carbon dioxide (Arterial CO2) were measured. The arterial partial pressure of oxygen (PaO2) and arterial carbon dioxide pressure (PaCO2) were measured, and the oxygenation index (OI) was calculated.

Conditions

• Respiration

Interventions

Timeline

Start date

2024-01-01

Primary completion

2024-03-16

Completion

2024-03-17

First posted

2024-02-08

Last updated

2024-03-21

Locations

1 site across 1 country: China

Source: ClinicalTrials.gov record NCT06247943. Inclusion in this directory is not an endorsement.